The morphology of the sensory neuron in the cockroach femoral tactile spine.

1. The cockroach femoral tactile spine contains a single bipolar sensory neuron. The mechanosensitive dendrite in the wall of the spine leads through the spine lumen to a cell body, and then to an axon that proceeds proximally along the femur.

The morphological basis of intracellular measurements in the cockroach tactile spine neuron.

The femoral tactile spine of the cockroach (Periplaneta americana) contains a single sensory neuron, which adapts rapidly and completely to step deformations of the spine. Techniques for stable intracellular recording from the tactile spine neuron have recently been established, allowing electrophysiological investigation of mechanotransduction and adaptation in this sensory neuron. However, intracellular recordings from the neuron produce a wide range of action potential heights and thresholds, raising the possibility that some penetrations are in adjacent, but closely coupled supporting glial cells.

Subconductance states in calcium-activated potassium channels from canine airway smooth muscle.

The single-channel patch clamp technique was used to analyze subconductance states in the 260 pS calcium-activated potassium channel from canine airway smooth muscle. More than sixty minutes of single channel data (greater than 87,000 events) from five excised patches were analyzed. Six subconductance amplitudes were clearly established to be 17, 33, 41, 52, 63 and 72% of the full conductance.

Intracellular nonlinear frequency response measurements in the cockroach tactile spine neuron.

The threshold of the cockroach tactile neuron increases strongly with depolarization by a process involving at least two time constants. This effect is probably responsible for the rapid and complete adaptation of the neuron's response to step inputs. A technique for intracellular recording and stimulation of the neuron has recently been established and this allows direct observation of the dynamic response of the neuronal encoder.

Dissociation and culture of mechanosensory neurons for patch clamp analysis.

Single mechanosensory neurons were isolated from chordotonal organs of adult cockroach antennae. Transmission and scanning electron microscopy showed that the soma and part of the mechanosensory ending survived the dissociation. In culture, outgrowth occurred from the ending.

Characterization of a calcium-activated potassium channel in human fibroblasts.

The cell-attached and inside-out patch clamp techniques were used to record single-channel currents from human epidermal fibroblasts. A large-conductance channel (320 pS in symmetric 140 mM KCl) with high potassium selectivity was observed in many patches, particularly those located at the borders of the cells. The channel exhibited both voltage and calcium sensitivity and, therefore, was regarded as a variety of the large-conductance calcium-activated potassium channels reported in many preparations.

Fractal and Markov behavior in ion channel kinetics.

Kinetic analysis of ion channel recordings attempts to distinguish the number and lifetimes of channel molecular states. Most kinetic analysis assumes that the lifetime of each state is independent of previous channel history, so that open and closed durations are Markov processes whose probability densities are sums of exponential decays. An alternative approach assumes that channel molecules have many configurtions with widely varying lifetimes.

Stretch-activated cation channels in human fibroblasts.

Nonconfluent fibroblasts are relatively depolarized when compared with confluent fibroblasts, and transient hyperpolarizations result from a range of external stimuli as well as internal cellular activities. This electrical activity ceases, along with growth and mitogenic activity, when the cells become confluent. A calcium-activated potassium conductance is thought to be responsible for these hyperpolarizations, but in human fibroblasts the large calcium-activated potassium channel is not stretch-activated.

Differential conduction at axonal bifurcations. I. Effect of electrotonic length.

1. Frequency-dependent differential conduction of action potentials into one daughter branch of the squid giant axon is demonstrated. 2.

Potassium channels in human and avian fibroblasts.

The cell-attached and excised inside-out patch-clamp techniques were used to study single-channel characteristics of potassium channels in cultured human and avian fibroblasts. Six different potassium channels were distinguished with conductances of 235 +/- 25, 190 +/- 57, 114 +/- 27, 77 +/- 14, 40 +/- 6 and 21 +/- 4 pS in symmetric 140 mM potassium solutions. The channels were separable by their conductances, ion-selectivities, voltage-sensitivities and kinetic properties.

Properties of synaptic transmission at the neuromuscular junction of the squid, Loligo opalescens.

1. Spontaneous and evoked synaptic activity were recorded from the muscles of squid fin and mantle. These spontaneous synaptic potentials were large (up to 30 mV) and pleomorphic.

A TTX-resistant propagating calcium action potential.

The cross-commissural (CC) cell in the supraesophageal ganglion of the giant barnacle, Balanus nubilus, was stimulated intrasomatically and antidromically in normal saline and 3 X 10(-7) M tetrodotoxin (TTX) saline. The action potential in normal saline contained both sodium and calcium components, each independently capable of propagation. Evidence that the action potential in TTX saline was calcium dependent included: the amplitude of the spike in TTX saline increased monotonically with increasing calcium; it was blocked by the calcium channel blockers La, Ni, Cd and Co; and equimolar substitution of Ba or Sr for Ca in TTX saline supported regenerative activity.

Regional properties of calcium entry in barnacle neurons determined with Arsenazo III and a photodiode array.

Calcium changes were simultaneously measured at many positions on individual neurons from the supraesophageal ganglion of the barnacle by detecting absorbance changes of the indicator dye Arsenazo III with a 10 X 10 photodiode array. These changes were correlated with positions on the stimulated cell determined from Lucifer yellow injections. Absorbance signals were found at all locations on the cells, demonstrating that calcium channels were distributed on the somata, axons, and neuropil processes.